System and method for monitoring congestion in communication systems

ABSTRACT

A system and method for monitoring congestion in a communication system including an external packet switched network. The communication system includes a plurality of interconnected host devices, such as base stations, consoles, zone controllers. To determine the presence of congestion on links between a pair of host devices, a series of sequential packets are transmitted between the pair. The sequentially transmitted packets are then monitor fluctuations in transmission delays and lost packets. These two criteria are used to identify congestion levels present on the various links in the communication system, and communications on the relevant interzone link are controlled based on the identified congestion level.

TECHNICAL FIELD OF THE DISCLOSURE

This disclosure relates generally to communication systems and moreparticularly to a system and method for monitoring congestion incommunication systems.

BACKGROUND OF THE DISCLOSURE

Communication systems typically include a plurality of dispatch consolesand communication units, such as mobile or portable radio units, thatare geographically distributed among various base sites and consolesites. The communication units wirelessly communicate with the basesites and each other, and are often logically divided into varioustalkgroups. Communication systems may be organized as trunked systems,where a plurality of radio frequency (RF) communication resources areallocated amongst multiple users or groups by assigning the base siteswithin a coverage area on a call-by-call basis, or as conventional(non-trunked) systems where RF communication resources are dedicated toone or more users or groups. In trunked systems, or in mixed trunked andconventional systems, there is usually provided a centralcontroller/server (sometimes called a “zone controller”) for allocatingRF communication resources among a group of sites.

Many such communication systems use Internet Protocol (IP) to transportpacket data representative of voice, video, data or control trafficbetween endpoints (or “hosts” in IP terminology). In such systems, hostdevices, including base stations, consoles, zone controllers, and insome instances, wireless mobile or portable radio units in differentzones, are logically interconnected by various routers forming an IPnetwork. Data is divided into IP packets called datagrams, which includeaddressing information (e.g., source and destination addresses) thatenables the routers of the network to transport the packets to thespecified destination(s).

Typically, systems utilizing IP to transport packet data include variouscongestion control protocols. For example, one well known congestionprotocol, commonly referred to as explicit congestion notification (ECN)marking, is described in U.S. patent Pub. Ser. No. 2006/0015639. Insystems utilizing ECN marking, exit routers for each of the zones in acommunication system assess the availability of inter-zone resources inthe IP network and update an ECN field in transmitted control packets toindicate the level of congestion.

However, many communication systems today also make use of an externalpacket switched network, such as Multi-Protocol Label Switching (MPLS),to reduce costs by reusing network infrastructure and bandwidth used byother types of networked systems. Such external packet switched networkstypically do not provide any congestion notification or avoidancemechanisms appropriate for real-time voice applications. As a result,congestion within the external packet switched network cannot be readilydetected by many communications systems, resulting in dropped packetswhen such congestion is present.

BRIEF DESCRIPTION OF THE FIGURES

Various embodiment of the disclosure are now described, by way ofexample only, with reference to the accompanying figures.

FIG. 1 shows one embodiment of a communication system in accordance withthe present disclosure.

FIG. 2 shows one embodiment of a method for determining the presence ofcongestion in a communication system in accordance with the presentdisclosure.

FIG. 3 shows one embodiment of a method for determining a congestionlevel in accordance with the present disclosure.

Skilled artisans will appreciate that elements in the figures areillustrated for simplicity and clarity and have not necessarily beendrawn to scale. For example, the dimensions and/or relative positioningof some of the elements in the figures may be exaggerated relative toother elements to help improve the understanding of various embodimentsof the present disclosure. Also, common but well-understood elementsthat are useful or necessary in a commercially feasible embodiment arenot often depicted in order to facilitate a less obstructed view ofthese various embodiments of the present disclosure. It will be furtherappreciated that certain actions and/or steps may be described ordepicted in a particular order of occurrence while those skilled in theart will understand that such specificity with respect to sequence isnot actually required. It will also be understood that the terms andexpressions with respect to their corresponding respective areas ofinquiry and study except where specific meaning have otherwise been setforth herein.

DETAILED DESCRIPTION OF THE DISCLOSURE

The present disclosure provides a system and method for monitoring andresponding to congestion in a communication system incorporating anexternal packet switched network, and for ensuring that calls arereliably set up and audio quality is sufficient even in the presence ofsuch congestion. The communication system includes a plurality ofinterconnected host devices, such as base stations, consoles, zonecontrollers. To determine the presence of congestion on links between apair of host devices, a series of sequential packets are transmittedbetween the pair. The sequentially transmitted packets are thenmonitored to determine two individual criteria: fluctuations intransmission delays and lost packets. These two criteria are used toidentify congestion levels present on the various links in thecommunication system, and communications on the relevant interzone linkare controlled based on the identified congestion level.

Let us now discuss the present disclosure in greater detail by referringto the figures below. FIG. 1 illustrates a communication system 100having a plurality of zones 102. Each zone 102 comprises a plurality ofbase sites 104 in communication with a core router 106. Each base site104 may comprise one or more repeaters that communicate, using wirelesscommunication resources, with communication units (not shown) within aspecific coverage area. The communication units may comprise mobile orportable wireless radio units, cellular radio/telephones, videoterminals, portable computers with wireless modems, or any otherwireless devices.

The core router 106 in each zone 102 is also coupled with a zonecontroller 108. The zone controller 108 provides overall call controlfor routing payload (e.g., voice, data, video, etc.) and controlmessages between and among the various base sites 104 within thecorresponding zone 102. Each zone controller 108 is also coupled with anexit router 110. The exit routers 110 from each zone 102 are alsocoupled to one another via network 112 to allow for interzonecommunications. For purposes of this disclosure, a communication pathbetween two zones is referred to herein as an interzone link, whilecommunication paths within a zone are referred to herein as site links.

In one embodiment, the base sites 104, the zone controller 108, the exitrouter 110, and the network 112 may be coupled using T1 lines, E1 lines,fiber optic lines, wireless links, Ethernet links, or any other suitablemeans for transporting data between the various components. Inaccordance with the present disclosure, at least a portion of network112 also includes an external packet switched network, such as MPLS(please define acronym), to provide additional communication resourcesfor the network 112.

Of course, practitioners skilled in the art will appreciate that thesystem 100 may also include various other elements not shown in FIG. 1.For example, although only three zones 102 and two base sites 104 perzone are illustrated, the system 100 may include any number of zones102, each having any number of base sites 104. Each zone 102 in thesystem 100 may also include one or more console sites. The system 100may also be linked to a public switched telephone network (PSTN), apaging network, a facsimile machine, or the like. The communicationsystem 100 may also be connected to a number of additional contentsources, such as the Internet or various Intranets.

In accordance with the present disclosure, a series of sequentialpackets (also referred to herein as monitoring packets) are transmittedalong each interzone link. The monitoring packets are then monitored, byeach zone controller to determine two separate congestion criteria. Moreparticularly, the monitoring packets are monitored to determine anyfluctuations in the transmission delay (also known as jitter) of themonitoring packets as well as to determine whether any of the monitoringpackets were lost during transmission. Based on these two criteria, thecommunication system is capable of assessing the congestion level ofvarious interzone links in the system, regardless of the whether theinterzone link is utilizing an external packet switched network.

Referring now to FIG. 2, one embodiment of a method for utilizing aseries of monitoring packets in accordance with the present disclosureis described. A zone controller 108 receives a monitoring packet on aninterzone link in step 202. In step 204, it is determined whether themonitoring packet was either delayed or dropped.

There are multiple ways in which the zone controller may determine thetransmission delay for a particular monitoring packet. For example, inone embodiment, monitoring packets may be transmitted between zonecontrollers at predetermined known intervals. In this case, the amountof time that each packet is delayed may be determined by the receivingzone controller by simply comparing the time when a monitoring packetwas received with the time when the monitoring packet was expected to bereceived.

Often times, however, it is not possible to transmit the monitoringpackets at set intervals due to transmission priorities for other typesof control packets. Thus, alternatively, the monitoring packets mayemploy the use of a time stamp. More specifically, each monitoringpacket is sent along with a time stamp indicative of the time that themonitoring packet was transmitted. The receiving zone controller thenmeasures the time stamp against its own internal clock to determine thedelay.

For purposes of step 204, a monitoring packet may be considered to bedelayed if the measured delay is greater than a predetermined amount oftime. In another embodiment, the monitoring packet may be considereddelayed if the measured delay is a certain amount greater than anexpected delay on the interzone link (e.g., a certain amount greaterthan the typical transmission latency for the interzone link). In yetanother embodiment, a monitoring packet may be considered delayed if thedelay associated with the received monitoring packets is a predeterminedamount of time greater than a previously received monitoring packet.

Similar to the case of monitoring packet delay times, loss of packetsmay also be determined using various methodologies. For example, if themonitoring packets are transmitted at predetermined intervals, thereceiving zone controller may know when and/or how many packets areexpected. If an expected monitoring packet is not received within acertain time frame, then it can be considered lost.

Alternatively, if the monitoring packets are not sent at predeterminedintervals, but are sent intermittently, sequence numbers may be providedwithin each transmitted monitoring packet. In this case, when amonitoring packet with a specific sequence number is received by thezone controller 108, the zone controller 108 may compare that sequencenumber with that of previously received monitoring packets to determineif any packets were dropped.

In one embodiment, the monitoring packets are comprised of controlpackets that are also used by the system for other functions, such asresource request signals or resource grant signals. In this way,congestion may be monitored on a link without adding additional trafficon the link, which may be especially useful for links with lowbandwidth. Of course, the communication system may also utilizededicated monitoring packets that are used solely for monitoring thecongestion criteria. It should of courses be understood that one set ofmonitoring packets may be used for determining both delay times andpacket loss. Alternatively, however, the set of monitoring packetstransmitted for use in determining delay times may be different than themonitoring packets transmitted for use in determining packet loss.

Regardless of whether it is determined in step 204 that a monitoringpacket has been delayed or dropped, the next step determines whether thereceiving zone controller is operating in a “congestion monitoringstate.” More particularly, if it is determined that a monitoring packethas either been delayed or dropped, it is then determined whether thezone controller 108 is currently operating in a congestion monitoringstate in step 206. However, if it is determined that a monitoring packethas not been delayed or dropped in step 204, the process determineswhether the zone controller 108 is currently operating in a congestionmonitoring state in step 212.

Turning first to step 206, if the zone controller is determined not tobe operating in a congestion monitoring state, the zone controller 108enters the congestion monitoring state in step 208, begins a windowtimer in step 210, and returns to step 202 to receive the next packet.The window timer may be set to run for any predetermined period of timeand essentially establishes a time window during which packet delaytimes and packet loss are continuously monitored. If, in step 206, it isdetermined that the zone controller 108 is already operating in acongestion monitoring state, process proceeds to step 214.

Turning now to step 212, if the zone controller is determined not to beoperating in a congestion monitoring state, the process simply returnsto step 202 without engaging the congestion monitoring state. However,if, in step 212, the zone controller is determined to be operating in acongestion monitoring state, the process proceeds to step 214.

In step 214, a record is made indicating an amount of time by which thecurrent monitoring packet was delayed, or indicating whether the currentmonitoring packet was dropped. In step 216, it is determined whether thewindow timer has expired. If the window timer has not yet expired, theprocess returns to step 202 and the next monitoring packet is received.As a result of step 202 through 216, once a monitoring packet isdetermined to be either delayed or dropped, a congestion monitoringstate is engaged and a window timer is started. During the time window,the zone controller 108 continues to monitor whether any monitoringpackets have been delayed or dropped. Once, the window timer hasexpired, the process proceeds to step 216.

In step 216, it is determined whether there is an indication ofcongestion on the interzone link. As will be discussed in more detailwith regards to FIG. 3, the amount of congestion indicated on aninterzone link is related to the fluctuations in monitoring packet delaytimes (i.e., jitter) and the amount of monitoring packets lost duringthe time window.

If congestion is indicated in step 216, the zone controller initiatesthe appropriate call control procedures based on the amount of indicatedcongestion in step 218. The window timer is then reset in step 220, andthe process returns to step 202 whereby monitoring packets are continuedto be monitored during the next time window to again determine packetdelays and drops. If congestion is not indicated in step 216, the zonecontroller exits the congestion monitoring state, and the processreturns to step 202.

In the exemplary embodiment illustrated in FIG. 2, the zone controllerdoes not enter a congestion monitoring state, and thus does notdetermine an amount of congestion based on packet jitter and drops,until a monitoring packet is found to have been either delayed ordropped. In this way, processing power in the zone controller isconserved during times when congestion is not present. However, oneskilled in the art would understand that preset time windows may bemonitored to determine packet delay times and losses on a continuous orperiodic basis.

One skilled in the art would also understand that rather than obtainingpacket delay times and losses during set time windows in order to assesscongestion, the zone controller may alternatively be configured todetermine packet delay times and losses for a specific number ofpreviously received monitoring packets. The zone controller may also beconfigured to maintain a continuous value that is either incremented ordecremented by a certain amount based on the characteristics of eachsubsequent monitoring packet.

Turning to FIG. 3, one exemplary embodiment of a method is described fordetermining the amount of congestion on an interzone link based on thepacket delays and losses obtained in FIG. 2. More particularly, FIG. 3illustrates one exemplary method for performing steps 216 and 218. Thus,for purposes of this embodiment, it is assumed that both delay times andpacket losses have already been determined for a set time window.

The amount of jitter for monitoring packets received during the timewindow is determined in step 302. More particularly, as noted above, theamount of jitter is determined based on the fluctuations in delays ofthe received monitoring packets. For example, in one embodiment, theamount of jitter may be based on the average of the delays that exceed apredetermined threshold during the time window. In another embodiment,the amount of jitter may be based on the amount of times that packetdelays exceeded the predetermined threshold. In yet another embodiment,the amount of jitter may also be based on the percentage of packets thatexceed a predetermined threshold. In each scenario described above, thepredetermined threshold may be based on a set amount of delay.Alternatively, the predetermined threshold may be based on a certainamount of delay above a minimum delay level or expected latency delayfor each particular link.

In step 304, a first congestion level is determined based on the amountof determined jitter. For example, in the simplest embodiment, if thejitter exceeds a predetermined threshold, then the interzone link isconsidered congested, whereas if the jitter does not exceed apredetermined threshold, then the interzone link is not consideredcongested. However, as would be understood by one skilled in the art, itwould be desirable to allow for a plurality of different congestionlevels based on the amount of jitter. Thus, for purpose of theembodiment described in FIG. 3, it is assumed that three thresholdlevels are utilized by the zone controller 108 in determining congestionlevels based on jitter. More particularly, if the amount of jitterexceeds a first threshold, the interzone link is considered to belightly congested. If the amount of jitter exceeds a second higherthreshold, the congestion is considered intermediate. If the amount ofjitter exceeds yet a third higher threshold, then the interzone link isconsidered to be heavily congested.

The amount of dropped monitoring packets during the time window isdetermined in step 306. The amount of dropped packets may be basedeither on the total number of dropped monitoring packets during the timewindow or based on a percentage of monitoring dropped packets to thetotal number of monitoring packets received during the time window.

In step 308, a second congestion level is determined based on thedetermined amount of dropped monitoring packets. Similar to step 304,congestion may simply be considered to be present if the amount ofdropped monitoring packets exceeds a certain threshold level. However,as in the case described above with regards to jitter, for purpose ofthe embodiment described in FIG. 3, it is assumed that three thresholdlevels are utilized by the zone controller. More particularly, if theamount of dropped packets exceeds a first threshold, the interzone linkis considered to be lightly congested. If the amount of dropped packetsexceeds a second higher threshold, the congestion is consideredintermediate. If the amount of dropped packets exceeds yet a thirdhigher threshold, then the interzone link is considered to be heavilycongested. It should of course be understood that steps 306 and 308 maybe performed either concurrently with steps 302 and 304, or before orafter steps 302 and 304.

Upon determining the first and second congestion levels, the zonecontroller determines a final congestion level based on whether eitherof the first or second congestion level was indicative of heavycongestion in step 310. Thus, if either the first or second congestionlevel is indicative of heavy congestion, then the zone controller 108begins controlling communications on that interzone link based on a setof rules for heavy congestion in step 312. This may involve, forexample, permitting transmission of emergency calls while rejecting anyfollow-on push-to-talk requests on existing group calls. This may alsoinvolve terminating a portion or percentage of the lowest priorityexisting calls (e.g., individual and telephony calls). For example, inthe embodiment described in FIG. 3, if it is determined that there isheavy congestion for a certain time window, a predetermined portion orpercentage of the lowest priority calls may be terminated. If there isstill heavy congestion detected upon a subsequent time window, thenadditional lowest priority calls may be terminated at that time. Thisprocess would repeat and a portion or percentage of the lowest prioritycalls may continue to be terminated for each subsequent time windowuntil a lower congestion level is detected. As a result of this process,the audio quality of the highest priority calls (such as emergencycalls) is preserved.

If neither the first nor the second congestion levels indicate heavycongestion, it is determined if either the first or second congestionlevels indicate intermediate congestion in step 314. If either isindicative of intermediate congestion, then the zone controller beginscontrolling communications on the interzone link based on a set of rulesfor intermediate congestion in step 316. This may involve, for example,permitting transmission of emergency calls and allowing any follow-onpush-to-talk requests on existing group calls, but blocking and/orqueuing new group calls.

If neither the first or second congestion levels indicate lightcongestion, it is determined if either the first or second congestionlevels indicate light congestion in step 318. If either is indicative ofintermediate congestion, then the zone controller begins controllingcommunications on the interzone link based on a set of rules for lightcongestion in step 318. This may involve, for example, providing awarning to a network manager that some congestion has been identified onthe interzone link.

If neither the first or second congestion level indicates lightcongestion, then it is determined that there is no congestion andcommunications on the interzone link are processed as normal in step320. If any calls had been queued due to the detection of congestionduring prior time windows, this step may also involve processing atleast a portion of the previously queued calls. For example, in oneembodiment, upon determining that there is no congestion for a timewindow, a portion of the calls that were previously queued may beprocessed, preferably in order of their priority from highest to lowest.If no congestion is again detected during the subsequent time window,then additional highest priority calls would be processed at that time.The process would repeat until the queue is empty, or until congestionis detected.

Thus, in the illustrated embodiment, the final congestion level of eachinterzone link is determined based on the highest level of congestionindicated by either the first congestion level (based on jitter) or thesecond congestion level (based on the amount of dropped packets). Ofcourse, other methods may also be used and either one of the first orsecond congestion levels may be weighted more or less than the other.

By means of the aforementioned disclosure, each zone controller 108 canmanage communications within the system 100 based on congestion thatoccurs in the IP network as well as in the external packet switchednetwork. As a result, there is a significant decrease in the risk thattransmitted communications would be dropped due to the presence ofundetected congestion.

Further advantages and modifications of the above described system andmethod will readily occur to those skilled in the art. For example, thepresent disclosure may be used to continuously or periodically monitorcongestion levels on each interzone link. Alternatively, the presentdisclosure may be used to monitor congestion on an interzone link onlyduring a call on the interzone link. The monitoring packets describedherein may also be dedicated packets used solely for monitoringcongestion or control packets used by the system for other functions,such as resource request signals or resource grant signals.

Additionally, while the embodiment described above has been illustratedin regards to congestion monitoring for interzone links, it isunderstood that the present disclosure may also similarly be applied tosite links between a zone controller and a site controller (either inthe same zone or in different zones).

The disclosure, in its broader aspects, is therefore not limited to thespecific details, representative system and methods, and illustrativeexamples shown and described above. Various modifications and variationscan be made to the above specification without departing from the scopeor spirit of the present disclosure, and it is intended that the presentdisclosure cover all such modifications and variations provided theycome within the scope of the following claims and their equivalents.

1. A method for determining congestion in a communication systemincluding a plurality of host devices logically connected by one or morepaths in a packet switched network, the method comprising: receiving, ata first host device, a plurality of monitoring packets transmitted froma second host device; monitoring transmission delay times for at least afirst portion of the plurality of monitoring packets; determining afirst congestion level based on the transmission delay times; monitoringan amount of monitoring packets dropped for at least a second portion ofthe plurality of monitoring packets; determining a second congestionlevel based on the amount of monitoring packets dropped; and determininga final congestion level based on the first congestion level and thesecond congestion level, whereby communications between the first hostand the second host are controlled based on the final congestion level.2. The method of claim 1 further comprising determining an amount ofjitter for at least the first portion of the plurality of monitoringpackets based on fluctuations in the transmission delay times; andwherein determining a first congestion level comprises determining afirst congestion level based on the amount of jitter.
 3. The method ofclaim 2 wherein determining the first congestion level comprisesdetermining the first congestion level based on a comparison of theamount of jitter with at least one predetermined congestion levelthreshold; and wherein determining the second congestion level comprisesdetermining the second congestion level based on a comparison of theamount of packets dropped with at least one predetermined congestionlevel threshold.
 4. The method of claim 1 wherein monitoringtransmission delay times comprises monitoring transmission delay timesfor a predetermined window of time; and wherein monitoring the amount ofmonitoring packets dropped comprises monitoring the amount of monitoringpackets dropped during the predetermined window of time.
 5. The methodof claim 1 wherein determining a final congestion level comprisessetting the final congestion level to be indicative of the highest levelof congestion indicated by either the first congestion level or thesecond congestion level.
 6. The method of claim 1 further comprising,upon determining that the final congestion level is a first congestionlevel, controlling communications between the first and second hostdevices using a first set of protocols, wherein the first set ofprotocols include at least one of (a) permitting transmission of a newcall only if the new call is a high priority call (b) rejecting anyfollow-on push-to-talk requests for existing calls, and (c) terminatingat least a portion of the existing calls.
 7. The method of claim 6further comprising, upon determining that the final congestion level isa second congestion level, controlling communications between the firstand second host devices using a second set of protocols, wherein thesecond set of protocols include at least one of (a) permittingtransmission of a new call only if the new call is a high priority call,and (b) queuing a new call if the new call is not a high priority call.8. The method of claim 7 further comprising, upon determining that thefinal congestion level is a third congestion level, controllingcommunications between the first and second host devices using a thirdset of protocols, wherein the third set of protocols includes providinga warning to a network manager that congestion has been identified. 9.The method of claim 8 further comprising, upon determining that thefinal congestion level is indicative of no congestion, controllingcommunications between the first and second host devices using a fourthset of protocols, wherein the fourth set of protocols includesprocessing at least a portion of new calls that were previously queued.10. A method for determining congestion in a communication systemincluding a plurality of host devices logically connected by one or morepaths in a packet switched network, the method comprising: receiving, ata first host device, a plurality of monitoring packets transmitted froma second host device; determining that a first one of the plurality ofmonitoring packets was delayed or dropped; initiating a window timerupon determining that the first one of the plurality of monitoringpackets was delayed or dropped; monitoring transmission delay times forthe plurality of monitoring packets during a preset window of time basedon the window timer; monitoring an amount of monitoring packets droppedduring the present window of time; determining a first congestion levelbased on the transmission delay times for the plurality of monitoringpackets during the preset window of time; determining a secondcongestion level based on the amount of monitoring packets droppedduring the present window of time; and determining a final congestionlevel based on the first congestion level and the second congestionlevel, whereby communications between the first host and the second hostare controlled based on the final congestion level.
 11. The method ofclaim 10 wherein each of the first and second host devices comprises oneof a zone controller and a site controller.
 12. The method of claim 10further comprising determining an amount of jitter for the plurality ofmonitoring packets based on fluctuations in the transmission delaytimes; and wherein determining a first congestion level comprisesdetermining a first congestion level based on the amount of jitter. 13.The method of claim 12 wherein determining the first congestion levelcomprises determining the first congestion level based on a comparisonof the amount of jitter with at least one predetermined congestion levelthreshold; and wherein determining the second congestion level comprisesdetermining the second congestion level based on a comparison of theamount of packets dropped with at least one predetermined congestionlevel threshold
 14. The method of claim 13 wherein determining a finalcongestion level comprises setting the final congestion level to beindicative of the highest level of congestion indicated by either thefirst congestion level or the second congestion level.
 15. Acommunication system comprising: a first host device; a second hostdevice; and a network including a packet switched network for logicallycoupling the first and second host devices to one another by one or morepaths, wherein the first host device is configured to receive, from thesecond host device, a plurality of monitoring packets, monitortransmission delay times for at least a first portion of the pluralityof monitoring packets; and monitor an amount of monitoring packetsdropped for at least a second portion of the plurality of monitoringpackets; and wherein the first host device is further configured todetermine a first congestion level based on the transmission delaytimes; determine a second congestion level based on the amount ofmonitoring packets dropped; and determine a final congestion level basedon the first congestion level and the second congestion level; wherebycommunications between the first host and the second host devices arecontrolled based on the final congestion level.
 16. The system of claim15 wherein each of the first and second host devices comprises one of azone controller and a site controller.
 17. The system of claim 15wherein the fist host device is configured to determine an amount ofjitter for the plurality of monitoring packets based on fluctuations inthe transmission delay times; and determine the first congestion levelbased on the amount of jitter.
 18. The system of claim 17 wherein firsthost device is configured to determine the first congestion level basedon a comparison of the amount of jitter with at least one predeterminedcongestion level threshold; and wherein first host device is configuredto determine the second congestion level based on a comparison of theamount of packets dropped with at least one predetermined congestionlevel threshold
 19. The system of claim 18 wherein first host device isconfigured to determine the final congestion level based on the highestlevel of congestion indicated by either the first congestion level orthe second congestion level.
 20. The system of claim 15 wherein thefinal congestion level is capable of being at least one of a highcongestion level, an intermediate congestion level, a light congestionlevel, and a no congestion level, wherein, upon determining that thefinal congestion level is the high congestion level, the communicationsystem is configured to process communications between the first andsecond host devices using a first set of protocols, wherein the firstset of protocols include at least one of (a) permitting transmission ofa new call only if the new call is a high priority call (b) rejectingany follow-on push-to-talk requests for existing calls, and (c)terminating at least a portion of the existing calls; wherein, upondetermining that the final congestion level is the intermediatecongestion level, the communication system is configured to processcommunications between the first and second host devices using a secondset of protocols, wherein the second set of protocols include at leastone of (a) permitting transmission of a new call only if the new call isa high priority call, and (b) queuing a new call if the new call is nota high priority call; wherein, upon determining that the finalcongestion level is the light congestion level, the communication systemis configured to process communications between the first and secondhost devices using a third set of protocols, wherein the third set ofprotocols includes providing a warning to a network manager thatcongestion has been identified; wherein, upon determining that the finalcongestion level is the no congestion level, the communication system isconfigured to process communications between the first and second hostdevices using a fourth set of protocols, wherein the fourth set ofprotocols includes processing at least a portion of new calls that werepreviously queued.